DE19623570A1 - Temperature monitor with a Kapton film - Google Patents

Abstract

The device has a bimetallic switch mechanism (15) which switches when a predetermined temperature is exceeded. The switch mechanism (15) is held in a housing lower part (11). This housing part is closed by a cover part (12). A Kapton (RTM) film (22) is arranged between the housing lower part (11) and the cover (12). The film (22) provides a mechanical seal protecting against dust and moisture in between the housing lower part (11) and the cover (12). The thickness of the film is preferably greater than 100 micrometers. The edge of the cover (12) may compress the film (22) where it meets the edge of the cover (12) and a shoulder of the housing lower part. A bulge or raised part (31) may be formed around the inner edge of the cover (12). This presses into the film.

Description

The present invention relates to a temperature monitor a bimetal rear derailleur that switches at overtemperature, one the rear derailleur housing part, one the housing lower part closing cover part and a Kapton film, which are arranged between the lower housing part and the cover part is.

Such temperature monitors are from the prior art known.  

The housing of the known temperature monitors lower part and the cover part made of conductive material, preferably made of metal, so that they are very stable and pressure-resistant are.

The bimetal rear derailleur usually includes a spring washer, which is with its edge on the bottom of the lower housing part supports and carries a movable contact part in the middle, that pushes it against the inside of the lid part, where a fixed counter contact is arranged. About the moving contact Part is a bimetallic snap disc that is placed underneath their switching temperature rests without force on the spring washer. Such a temperature monitor is on the cover part and contacted the housing base, the current from the Cover part over the counter contact and the spring washer to the Lower housing part flows.

If the temperature of the bimetallic snap disc becomes impermissible raised, it jumps from its convex into a concave Form in which it against the force of the spring washer movable contact part stands out from the mating contact and thus opens the circuit. For this it is necessary that the Cover part is insulated from the lower housing part, what through the already mentioned Kapton film.

The Kapton film also covers the inside of the lid part, so that the edge is in its high temperature position here supporting bimetal snap disc no short circuit can produce between the cover part and the spring washer.

It is known to use another insulating film instead of the Kapton film to use the z. B. be made of Nomex or Teflon can. The thickness of the Kapton film is 75 µm, this thickness  is determined by the desired dielectric strength. It is noted that in the open state above the Kapton foil drops a voltage that corresponds to the level of the mains voltage can correspond.

Important for the operation of the temperature described so far guardian is that no dust, no moisture as well as none Liquid get inside this temperature monitor, to impair the function of the bimetal rear derailleur to avoid. Dust and liquid can e.g. B. un Desired leakage currents or isolation areas arise which negatively affects the reliable operation of the temperature monitor can influence. It can also damage the rear derailleur arise.

To achieve the required tightness, the stand the technology, the temperature monitors with connecting wires with epoxy, silicone or other coating compositions either whole or but only encased on the areas where penetration is possible for dust, water, oil etc. are present. These wrappings require additional costly operations.

In addition, it is known to work with connecting wires to provide the provided temperature monitor with shrink sleeves, to achieve electrical isolation.

Against this background, it is an object of the present invention the above-mentioned temperature monitor at constructive simple structure so that in an inexpensive way for a good seal between the lower part of the housing and the Cover part is taken care of.  

With the temperature monitor mentioned at the beginning, this task solved according to the invention in that the Kapton film, the preferably has a thickness which is greater than 100 μm, for a mechanical seal between the lower part of the housing and the cover part, the cover part preferably with its edge the Kapton film in its contact area between the edge and a shoulder of the lower housing part.

The object underlying the invention is achieved in this way completely solved.

The inventors of the present application have recognized that that the Kapton film surprisingly not only for electrical insulation, but also for Sealing between cover part and lower housing part used can be. This is due to the fact that the Kapton film made of a non-porous and non-linting material that also has a certain elasticity, so that it can be compressed to a certain extent. So far, the known temperature monitors have been used for final assembly such a compression of the Kapton film is always avoided, thus the required for the desired dielectric strength Thickness remains.

According to the invention, the Kapton film is preferably at least 25 µm thicker than is the case in the prior art was so she was in the support area between the edge of the lid partly and the shoulder of the lower housing part by this amount (25 µm) can be compressed. Outside the edition and press area remains the original thickness of the Kapton film more or less preserved, so that overall a very good one Sealing between cover part and lower housing part results.  

This section-wise compression of the Kapton film is after Knowledge of the inventors possible because, apart from the required elasticity has the further advantage that they don't squeeze small particles in this, lint etc. emits that get inside the temperature monitor and there lead to an impairment of operational safety could.

The inventors of the present application have recognized for the first time that these properties of the Kapton film match it Design allow the Kapton film not only for electrical Isolation, but also / alternatively for sealing against dust and moisture / liquid. The Thickness is chosen so that the necessary elec dielectric strength is achieved.

The present invention accordingly also relates to the use a Kapton film, preferably thicker than 100 µm, for dust and liquid tight sealing between a lower housing part and a lid that closes it part of a temperature monitor, one in the lower housing part arranged bimetal switchgear that switches in the event of overtemperature has, the lower housing part and the cover part preferred as made of conductive material, particularly preferably made of metal are made.

The advantages of this use have already been detailed above described.

In a further development, it is preferred if the cover part on the inside a bead running around the edge or rib that the Kapton film in the area of the support area at least partially constricted, the bead preferably has a thickness which is greater than 20 microns.  

The advantage here is that an even better mechanical seal tion is achieved in that the bead partially, so to speak penetrates the material of the Kapton film and as a kind Sealing lip works. By choosing the thickness of the Kapton film on the one hand and the thickness of the bead or sealing lip on the other can be ensured here that the required Dielectric strength is maintained, while on the other hand a sufficient depth of penetration can be achieved, so that also the desired mechanical seal is achieved.

Compared to the more flat deformation described above the Kapton film in the contact area between the edge of the lid partly and the shoulder of the lower housing part indicates the measure the circumferential bead on the one hand the advantage that choice of thicknesses described above can be ensured that the dielectric strength is maintained. The required Force to press the bead into the Kapton disc is namely less than the force required to pull the Compress Kapton film in the entire contact area. By the choice of the required when crimping the lower housing parts Lichen force can thus be ensured that the bead penetrates into the Kapton film and for mechanical sealing ensures that, however, no further, especially none inadmissible deformation of the Kapton film takes place.

While the Kapton film deformed in the entire contact area has the advantage that the deformation on a larger area and thus for a very good seal provides this good seal in the embodiment achieved with the bead that this like a kind of sealing lip penetrates into the Kapton material. Of course, both can Measures can also be used in combination.  

Further advantages result from the description and the attached drawing.

It is understood that the above and the following standing features to be explained not only in each specified combination, but also in other combinations or can be used alone, without the scope of to leave the present invention.

The invention is illustrated in the drawing and is in the following description explained in more detail. Show it:

Figure 1 shows a new temperature monitor in a sectional side view, in which the Kapton film is deformed in the area of its support surface (not visible). and

Fig. 2 shows an alternative cover part, which can be used in the temperature monitor from Fig. 1.

In Fig. 1, an embodiment of the new temperature monitor 10 is shown in an axial section. The temperature controller 10 comprises a cup-shaped lower housing part 11 and a lower housing part 11 closing off the cover portion 12, which rests on an inner circumferential shoulder 13 of the lower housing part. 11 The temperature monitor 10 is closed by a flange 14 of the lower housing part 11 , which presses the cover part 12 onto the circumferential shoulder 13 .

In the interior of the lower housing part 11 there is a bimetallic switching mechanism 15 , which is of conventional construction. It comprises a spring washer 16 which carries a movable contact part 17 , over which a bimetallic snap disk 18 is placed. The spring washer 16 is supported on a bottom 19 of the pot-shaped lower housing part and thus prestresses the movable contact part 17 against a fixed contact part 20 which is provided on the cover part 12 on the inside 21 thereof.

In this temperature monitor 10 , the lower housing part 11 and the cover part 12 are made of conductive material, preferably metal, so that a Kapton film 22 is provided which electrically insulates the cover part 12 from the lower housing part 11 . The temperature monitor 10 is contacted on the one hand via the cover part 12 and on the other hand via the lower housing part 11 , as is known per se.

In Fig. 1 it can also be seen that the Kapton film 22 extends over the entire inside 21 of the cover part 12 , an opening 23 being provided through which the movable contact part 17 projects.

The Kapton film 22 has a thickness indicated at 25, which is greater than 100 microns and is preferably 125 microns. Because of this thickness 25 , the lid part 12 can be pressed with its edge 27 onto the Kapton film 22 in its support area 28 by the flanged edge 14 onto the edge 13 such that the support area 28 is at least partially compressed. This compressed contact area 28 is indicated in FIG. 1, but the change in the thickness 25 in this area cannot be seen for reasons of illustration.

Since the Kapton film 22 is made of elastic, lint-free material, which is also not porous, a good mechanical seal between the cover part 12 and the lower housing part 11 can be ensured in this way. The compression of the support area 28 results in a particularly good mechanical seal, so that neither dust nor liquid / moisture can penetrate into the interior of the temperature monitor 10 . Of course, it is not required that cover part 12 and lower housing part 11 are made of electrically conductive material, other constructions are also conceivable in which, for. B. the cover part 12 is made of electrically insulating material and the fixed contact part 20 extends like a rivet through the cover part 12 and is contacted from the outside.

In such an embodiment, the Kapton film 22 only takes over the function of the mechanical seal, since electrical insulation is not required.

In the state shown in Fig. 1, the switching mechanism 15 has a temperature below its response temperature, so that it is in the closed state in which it is for a conductive connection between the fixed contact part 20 and thus the electrically conductive cover part 12 and the bottom 19 and thus the electrically conductive lower housing part 11 .

If the temperature of the switching mechanism 15 is now increased, the bimetallic snap disk 18 suddenly snaps from the convex shape shown into a concave shape and is supported on the underside of the cover part 12 with the interposition of the Kapton film 22 in such a way that it counteracts the movable contact part the force of the spring washer 18 lifts off the fixed contact part 20 .

In Fig. 2, an alternative cover part 12 'is shown, which can be used in the new temperature monitor from Fig. 1. This alternative cover part 12 'has in the region of its edge 27 on the inside 21 a bead 31 or a rib which has a thickness indicated at 32 of greater than 20 microns, preferably of 30 microns. In the assembled state, the bead 31 presses like a sealing lip in the region of the support area 28 into the material of the Kapton film 22 and thus ensures a mechanical seal between the cover part 12 'and the lower housing part 11 .

The thickness 25 of the Kapton film 22 and the thickness 32 of the bead 31 are coordinated with one another such that after the flanging edge 14 has been flanged, the remaining thickness of the Kapton film 22 in the area of the bead 31 is still sufficient to ensure the required dielectric strength. On the other hand, the thickness 32 is chosen so that the mechanical sealing is particularly good.

Claims (12)

1. Temperature monitor with an overtemperature switching bimetal switchgear ( 15 ), a switchgear ( 15 ) accommodating lower housing part ( 11 ), a lower housing part ( 11 ) closing cover part ( 12 ) and a Kapton film ( 22 ) between the lower housing part ( 11 ) and the cover part ( 12 ), characterized in that the Kapton film ( 22 ) provides a mechanical seal between the lower housing part ( 11 ) and the cover part ( 12 ). 2. Temperature monitor according to claim 1, characterized in that the Kapton film ( 22 ) has a thickness ( 25 ) which is greater than 100 microns. 3. Temperature monitor according to claim 1 or 2, characterized in that the cover part ( 12 ) with its edge ( 27 ) the Kapton film ( 22 ) in its support area ( 28 ) between the edge ( 27 ) and a shoulder ( 13 ) of the lower housing part ( 11 ) squeezes. 4. Temperature monitor according to one of claims 1 to 3, characterized in that the cover part ( 12 ) on its inside ( 21 ) in the region of the edge ( 27 ) surrounding bead ( 31 ) which the Kapton film ( 22 ) in the region of Support area ( 28 ) at least partially constricted. 5. Temperature monitor according to claim 4, characterized in that the bead ( 31 ) has a thickness ( 32 ) which is greater than 20 microns. 6. Temperature monitor according to one of claims 1 to 5, characterized in that the lower housing part ( 11 ) and the cover part ( 12 ) are made of conductive material. 7. Temperature monitor according to claim 6, characterized in that the lower housing part ( 11 ) and the cover part ( 12 ) are made of metal. 8. Use of a Kapton film ( 22 ) for dust-proof and liquid-tight sealing between a lower housing part ( 11 ) and a cover part ( 12 ) closing this, a temperature monitor ( 10 ), which is arranged in the lower housing part ( 11 ) and switches at overtemperature bimetal switching mechanism ( 15 ). 9. Use according to claim 8, characterized in that a Kapton film ( 22 ) with a thickness ( 25 ) of greater than 100 µm is used. 10. Use according to claim 8 or 9, characterized in that the lower housing part ( 11 ) and the cover part ( 12 ) are made of conductive material. 11. Use according to claim 10, characterized in that the lower housing part ( 11 ) and the cover part ( 12 ) are made of metal. 12. Use according to one of claims 8 to 11, characterized in that the cover part ( 12 ) on its inside ( 21 ) in the region of the edge ( 27 ) has a circumferential bead ( 31 ) which the Kapton film ( 22 ) in the region of Support area ( 28 ) at least partially constricted.